Stump cutter

ABSTRACT

The present disclosure provides a device and method that enable the efficient reduction of stumps. In one embodiment the stump removal methods and devices according to the present disclosure allow the operator to have a clear view of the work area during operation, and the ability to move the reduction device through a wide range of motion during operation. In one embodiment, the material reduction tool pivots relative to the chassis in the vertical plane about multiple pivot points. In some embodiments the device includes a retractable auxiliary control panel located at the end of the device opposite the material reduction tool. The control panel enables the operator to direct the movement of the device from the end of the device and thereby enable the device to maneuver through narrow spaces.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation of application Ser. No. 12/741,807,filed Sep. 1, 2010, which is a National Stage Application ofPCT/US2008/082322, filed Nov. 4, 2008, which claims benefit toprovisional patent application Ser. No. 61/020,92, filed on Nov. 6,2007, titled Stump Cutter Boom, the disclosures of which are incorporateby reference herein in their entirety.

TECHNICAL FIELD

The present disclosure relates to material reduction machines andmethods of using the machines and manufacturing the machines. Inparticular, the methods and machines according to the present disclosureare adapted to be used to remove tree stumps.

BACKGROUND

Various methods and machines for removing stumps are known. Generally,the stump reduction devices and associated methods can be divided intotwo types: those where the engine is mounted to the frame of the deviceand those where the engine is mounted to the articulating arm, whichsupports the cutting or grinding tool. The engine remains at a constantangle relative to the ground during operation in the first type ofmachine, whereas the engine operating angle changes during operation inthe second type of machine. Though the first type of machines provide aninherently compact layout, there are associated disadvantages relatingto the second type of machines (e.g., possible engine failure due toexcessive tilting and a higher than desired center of gravity).

Examples of the first type of stump reduction machine are disclosed inU.S. Pat. No. 6,014,996, titled Control System for Stump Cuttersassigned to Vermeer; and U.S. Pat. No. 7,011,124, titled Stump GrinderHaving Automatic Reversing Feed Assembly assigned to Tramor. Forexample, of the second type of stump reduction machine see U.S. Pat. No.6,026,781, titled Stump Cutter Safety System assigned to Rayco; and U.S.Pat. No. 6,230,770, titled Stump Chipper and Method for the OperationThereof assigned to Vermeer-Holland. The present disclosure generallyrelates to the first type of stump reduction devices and relatedmethods.

SUMMARY

The present disclosure provides a device and method that enable theefficient reduction of stumps. In one embodiment the stump removalmethods and devices according to the present disclosure allow theoperator to have a clear view of the work area during operation, and theability to move the reduction device through a wide range of motionduring operation. In one embodiment, the material reduction tool pivotsrelative to the chassis in the vertical plane about multiple pivotpoints.

In some embodiments the device includes a retractable auxiliary controlpanel located at the end of the device opposite the material reductiontool. The control panel enables the operator to direct the movement ofthe device from the end of the device and thereby enable the device tomaneuver through narrow spaces.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 a is a front left perspective view of a stump reducing machineaccording to an embodiment of the present disclosure;

FIG. 1 b is a back right perspective view of a stump reducing machine ofFIG. 1 a;

FIG. 1 c is a back left perspective view of a stump reducing machine ofFIG. 1 a;

FIG. 1 d is a front right perspective view of a stump reducing machineof FIG. 1 a;

FIG. 2 a is a top view of the stump reducing machine of FIG. 1 a showingthe path of the console;

FIG. 2 b is a top view of the stump reducing machine of FIG. 1 a showingthe path of the stump reduction tool;

FIG. 3 is a perspective view of a portion of the stump reducing machineof FIG. 1 a;

FIG. 4 is a left side schematic view of the stump reducing machine ofFIG. 1 a with the boom in the fully retracted position;

FIG. 5 is a right side schematic view of the stump reducing machine ofFIG. 1 with the boom in the fully retracted position;

FIG. 6 is a left side view of the machine as in FIG. 1, showing the boomlift cylinder in the fully extended position;

FIG. 7 a is a left side view of the machine as in FIG. 1, showing theboom lift cylinder in an intermediate position;

FIG. 7 b is a left side view of the machine as in FIG. 1, showing thepath of the stump reduction tool;

FIG. 8 is a left side view of the stump reducing machine with the guardtilted by a stump during a stump reduction operation;

FIG. 9 is a side view of a second embodiment of the stump reducingmachine according to the present disclosure;

FIG. 10 is a side view of a third embodiment of the stump reducingmachine according to the present disclosure;

FIG. 11 is an enlarged front side perspective view of the auxiliarycontrols of FIG. 1 a in a working position;

FIG. 12 is a side view of the auxiliary controls of FIG. 1 a in aworking position;

FIG. 13 is a rear side perspective view of the auxiliary controls ofFIG. 1 a in a stowed position;

FIG. 14 is a side view of the auxiliary controls of FIG. 1 a in a stowedposition;

FIG. 15 is a rear side perspective view of the auxiliary controls ofFIG. 1 a in a working position;

FIG. 16 is an exploded assembly view of the components of the auxiliarycontrols of FIG. 1 a;

FIG. 17 is side view that illustrates a prior art configuration adjacenta wall;

FIG. 18 is a side view that illustrates an embodiment of the presentdisclosure adjacent a wall; and

FIG. 19 is a side view that illustrates the path of a cutting wheel of aprior art configuration.

DETAILED DESCRIPTION

The stump reduction device according to the present disclosure is anydevice that is configured to cut, chip, or grind a tree stump. The stumpreduction device is referred to herein interchangeably as a stumpgrinder, stump cutter, or stump chipper.

Referring to FIGS. 1 a-d and 2 a-b, an embodiment of a stump reductiondevice 1 is shown. The stump reduction device 1 includes a chassis 30with a first end 32 and a second end 34. In the depicted embodiment, thestump reduction device 1 includes an engine 40 that is mounted betweenthe first end 32 of the chassis 30 and the second end of the chassis 30.The engine 40 is mounted to the chassis 30 rather than to a moving arm.The stump reduction device 1 also includes a control console 36 mountedto the chassis 30 such that it can be positioned adjacent the second end34 of the chassis 30. In the depicted embodiment, the control console 36is pivotally attached to the chassis 30 via a linkage assembly 38 (FIGS.1 c and 2 a). In addition, a secondary set of controls 42 is locatednear the first end 32 of the chassis 30, which enables an operator tocontrol the machine while standing at the first end 32 of the machine.The stump reduction device 1 includes a mount member 4 pivotallyconnected to the second end of the chassis 30, and a material reductionlinkage assembly 2 connected to the mount member 4. In the depictedembodiment, the mount member 4 and sweep cylinders 12 enable thematerial reduction linkage to pivot relative to the chassis 30 about avertical axis 18 through a sweep range θ. In the depicted embodiment thesweep range is between 60 and 90 degrees and is independent of thevertical position of the material reduction linkage 2. It should beappreciated that other sweep ranges are also possible.

Referring to FIGS. 3-8, the components of a first embodiment of thematerial reduction linkage assembly 2 are identified and described ingreater detail. In the depicted embodiment the material reductionlinkage assembly 2 includes a first linkage 6 and a second linkage 5,each pivotally connected to the mount member 4. Each of the firstlinkage 6 and the second linkage 5 is also pivotally connected to athird linkage 7. In the depicted embodiment, the first linkage 6 isshown as a rigid bar. In the depicted embodiment the third linkage 7includes an upper end and a lower end. The lower end supports a gearbox,which supports a material reduction tool 3, shown as a cutter wheel, andthe upper end supports a hydraulic motor 8 that drives the rotation ofthe material reduction tool 3 via a gear box assembly 9. A drive shaftwithin the third linkage 7 connects the gear box assembly 9 with themotor 8.

Still referring to FIGS. 3-8, the material reduction linkage assembly 2further includes a lift cylinder 11 connected between the mount member 4and the second linkage 5. The lift cylinder 11 can be a hydrauliccylinder arranged to raise and lower the assembly. The depictedembodiment further includes a guard 10 movably supported over thematerial reduction tool 3. The guard 10 is shown as a plate memberincluding a trailing edge 44 and a leading edge 46. In the depictedembodiment, the guard 10 is pivotally mounted to the portion of thethird linkage 7 referred to herein as the gusset 13. In the depictedembodiment, the guard plate includes a raised middle section 48 andlower outwardly extending side flanges 50, 51. It should be appreciatedthat many other alternative embodiments are possible. For example, someembodiments may include more linkages, other embodiments may includefewer linkages, and yet other embodiments may include differentlyarranged or configured linkages and guards.

Referring to FIGS. 4-8, the operation of the material reduction linkageassembly 2 is described in greater detail. FIGS. 4 and 5 depict the leftand right sides of the material reduction linkage assembly 2 fullyraised in an up most position, FIG. 6 depicts the left side of thematerial reduction linkage assembly 2 fully lowered in a down mostposition, and FIG. 7 a depicts the left side of the material reductionlinkage 2 in an intermediate position. In the depicted embodiment the upmost position corresponds with the lift cylinder 11 being fullyretracted, and the down most position corresponds with the cylinderbeing fully extended. The position of the material reduction linkageassembly 2 in a vertical plane is controlled by the lift cylinder 11,and the position of the material reduction linkage assembly in ahorizontal plane is controlled by the sweep cylinders 12. In thedepicted embodiment the horizontal and vertical positions areindependently controlled.

Still referring to FIGS. 4-8 the angle between a horizontal plane and aline passing through the leading edge 46 and trailing edge 44 of theguard 10 is defined herein as the tilt angle δ. In the depictedembodiment, the variation in the tilt angle δ is less than about 5-35degrees throughout the range of motion of the material reduction linkageassembly 2, unless it is being deflected (i.e., acted on by an outsideforce). More preferably, the tilt angle δ is less than about 15 degrees(e.g., between 0 and 15 degrees). This relative low variation in tiltangle δ can be desirable because this enables the guard 10, at least inpart, to cover the material reduction tool 3 during operation.Occasionally, the guard 10 is acted on by an outside force duringoperation, for example, the guard 10 is deflected when the materialreduction tool 3 climbs a stump as shown in FIG. 8.

In the depicted embodiment the guard 10 is configured such that the tiltangle δ can be about 35 degrees greater than the undeflected tilt angle.In some embodiments the deflected tilt angle can be between 5 to 45degrees relative to the undeflected tilt angle. It should be appreciatedthat other tilt angles and tilt angle ranges are also possible (e.g.,0-180 degrees). Since according to some embodiments of the presentdisclosure the variation in undeflected tilt angle is less than in priorart configurations, the stump cutter of the present disclosure is moreeffective in cutting stumps that are relatively vertical and tall. FIGS.17 and 18 illustrate that a low variation in tilt angle δ can result ina larger effective range of motion of the guard as compared to a priorart configuration where the tilt angle δ is larger. The configurationillustrated in FIG. 18 is more adept at working near walls or otherobstructions than the prior art configuration illustrated in FIG. 17.The range of motion of the guard in the embodiment shown in FIG. 18 isabout the same as the range of motion of the guard in the prior artconfiguration shown in FIG. 17, but due to the lower tilt angle δ of theguard shown in FIG. 18, the stump cutter is more effective in cuttingnear the obstruction (e.g., a wall).

Referring to FIG. 7 a, a full path of the material reduction tool 3 in avertical plane is shown. In the depicted embodiment the path isconsistent and partially dictated by the particular lengths of thelinkages, which in the depicted embodiment remains constant duringoperation. The path includes a component that extends in a verticaldirection (up and down relative to the ground surface 16) referenced asH, and a component that extents radially (towards and away from themount member 4) referenced as B. The depth of the plunge relative to theground surface 16 is referenced as D, and the radial distance from thepivot axis 18 to the center of the material reduction tool 3 isreferenced as C. In one embodiment C is about 51 inches and D is about23 inches. In the depicted embodiment the distance H is significantlylarger than B, meaning that the material reduction tool 3 does not movemuch radially when it is raised and lowered. In the particularembodiment shown, the value of B is about 35 inches and the value of His about 69 inches, therefore, the ratio of B:H is about 0.5. In thedepicted embodiment the material reduction linkage 2 is configured toachieve the desired ratio. In a prior art system wherein the cuttingtool is mounted to an arm that pivots in a vertical plane about a singleaxis, the arm would need to be substantially longer than the linkage 5to achieve a radius of curvature that would enable a ratio of B:H to bewithin the above range. If in the depicted embodiment the length of thesecond linkage 5 is about X feet long, to achieve the same B:H ratiousing an arm that pivots in a vertical plane about a single axis, thearm would need be over 2X feet long. A low B:H ratio can also bedesirable because machines with a low B:H ratio are less likely to havetheir cutting tools inadvertently contact material as they are raisedbecause their cutting tools do not swing as far outwards away from themachines as they are raised.

In a prior art configuration with the arm being about X feet long, theradius of curvature is significantly smaller (see FIG. 19). The priorart configuration shown in FIG. 19 is also not able to cut as verticallyinto the ground as compared to the embodiment of the present disclosure.

Referring to FIG. 7 b, the path of the material reduction tool isdescribed in greater detail. The vertical distance from the center(rotational axis) of the material reduction tool 3 at its highestposition to the position where the material reduction tool is furthestaway from the pivot axis 18 is shown as Y2. The vertical distance fromthe center (rotational axis) of the material reduction tool 3 at itslowest position to the position where the material reduction tool isfurthest away from the pivot axis 18 is shown as Y1. The horizontaldisplacement that corresponds with the distance Y2 is shown as X2. Thehorizontal displacement that corresponds with the distance Y1 is shownas X1. The distance from the lower pivot point of the second linkage 4to the ground surface is shown as Y3. In the depicted embodiment X1 isless than X2 and Y1 is greater than Y2. The depicted configurationallows the material reduction device to move essentially verticallywhile in operation and retract towards the chassis 30 when in transport.In one embodiment X1 is about 9 inches, X2 is about 14 inches, Y1 isabout 33 inches, Y2 is about 23 inches, and Y3 is about 21 inches. Insome embodiments the ratio between X1:Y1 is between zero to 0.3 and theratio between X2:Y2 is about 0.5-0.7. In some embodiments the ratiobetween X1:X2 is about to 0.5-0.7.

In a prior art configuration with the single pivot arm shown in FIG. 19,the path of the material reduction tool is not as vertical below groundand more vertical above ground as compared to the depicted embodiment ofthe stump cutter according to the present disclosure. It is typicallypreferable that the path of the material reduction tool be more verticalbelow ground and move curved back towards the machine above ground. Theability to move the reduction tool in the substantially verticaldirection allows the operator to remove stumps with fewer readjustmentsto the position of the stump cutter. Furthermore, the ability of thereduction tool to move back (retract) towards the machine when thereduction tool is above ground makes the machine more compact fortransport.

Referring to FIG. 9, a second embodiment of the material reductionlinkage 2′ is shown. The alternative embodiment includes a number of thesame components described above, which are referenced with the samenumbers. In the depicted embodiment the linkage 6 is shown as a cylinder17 instead of a fixed length bar as in the first embodiment. In thesecond embodiment, the cylinder 17 can extend and retract, allowing forthe path of the material reduction tool in a vertical plane to bevaried. The variable path in the vertical plane can allow the operatorto more efficiently remove stumps of various shapes and sizes. Themachine according to the second embodiment can enable the operator tocut almost vertically such that the ratio of B:H (more particularly,X1/Y1) is almost zero or alternatively to cut horizontally. The range ofB:H in the second embodiment can vary between 0-0.7. This embodiment canbe incorporated with a control system that automatically varies the cutpath to more efficiently reduce the stumps. The depicted configurationcan also have storage and transportation related advantages, as thelinkage assemblies can be pulled up and stowed in a compact position onthe second end of the material reduction device 2′, thereby shorteningthe overall length of the machine.

Referring to FIG. 10, a third embodiment of the material reductionlinkage 2″ is shown. The alternative embodiment includes a number of thesame components described above, which are referenced with the samenumbers. The depicted embodiment includes a cylinder 19 that isconnected between the guard 10 and the third linkage 7. In the depictedembodiment, the guard can be raised and lowered as desired. The depictedfeature can be desirable, as the operator can prevent the guard fromjamming into the stump as it climbs. In some embodiments, the cylinder19 can be configured to allow the guard to float over most objectswithout operator intervention. For example, cylinder 19 and liftcylinder 11 could have position sensors that detect the amount ofcylinder stroke. Based on the amount of stroke at cylinder 11, acontroller could regulate the stroke of cylinder 19.

The material reduction devices 2, 2′, 2″ embody several other additionalcommon advantages. Because material reduction tool 3 can be configuredto not significantly arc inward toward the machine 1 when the materialreduction tool 3 is lowered below grade, it is possible to maintainenough space for the cut chip volume to vacate the cut region, therebyminimizing the power and time that would otherwise be lost due tore-cutting chips. In addition, as sweep occurs, the width swept by thematerial reduction tool 3 is more constant when measured from the frontof the material reduction device because the distance C is more constantcompared to many prior art machines. The more constant C can bedesirable, as it can minimize the need for an operator to re-positionthe machine to cut roots extending outward from the stump below grade.The above specification, examples, and data provide a completedescription of the manufacture and use of the composition of theinvention. Since many embodiments of the invention can be made withoutdeparting from the spirit and scope of the invention, the inventionresides in the claims hereinafter appended.

Referring generally to FIGS. 11-16, the secondary set of controls 42located near the first end 32 of the chassis 30 are described in furtherdetail. In the depicted embodiment, the secondary set of controls 42includes control panel 52 connected to a linkage assembly 54 that can bepivoted towards the first end 32 into a stowed position (FIGS. 13, 14)or can pivot away from the first end 32 towards the operator for use inthe working position (FIGS. 11, 12, 15). In the stowed position, thecontrols 42 are in a more protected orientation than in the workingposition. In the stowed position the control panel 52 is faced towardsthe first end 32 of the machine. The pivoting features also enable easyaccess to other machine components for service or maintenance, as thecontrols 42 can be moved out of the way as necessary.

Referring to FIG. 11, in the depicted embodiment the control panel 52includes a forward and reverse control 56 and a left or right steeringcontrol 58, which together enable an operator to change the position ofthe machine while standing at the first end 32 of the machine. Inparticular, it enables the operator to walk in line with the machine.This function is particularly advantageous for job sites that requiremaneuvering the machine through tight and narrow spaces (e.g., a gate).It should be appreciated that in other embodiments the controls on thecontrol panel 52 can include other, or all the, functions available tothe main control panel 36. In the depicted embodiment, the controls 42can be operably connected to the machine via wires or, alternatively,wirelessly.

Referring to FIGS. 11-16, in the depicted embodiment the linkage 54 is afour bar type linkage that pivots to an over center position in thestowed position, thereby maintaining the controls 42 in the stowedposition until the operator wants to use the controls 42. The overcenter arrangement of the linkage avoids the need for pins, latches, orother secondary mechanisms for securing the controls 42 in the stowedposition. The linkage 54 includes control mount 60. The control mount 60(also referred to as the first linkage) includes a first lower end 62that is shown secured to a lower blade mount 64. In the depictedembodiment the blade mount 64 is configured to be bolted to the firstend 32 of the machine and is configured to support a blade 66. The blade66 is configured to be used to push piles of wood chips. In the depictedembodiment the blade is connected to the blade mount 64 such that it canbe raised and lowered by extending or retracting a hydraulic cylinder 68(FIGS. 11, 13, and 15). The control mount 60 includes a second upper end70 that includes pivot connections for the second linkage 72 and thethird linkage 74. In the working position the control panel 52 in thedepicted embodiment extends away from the machine to avoid theoperator's feet being below the blade 66, which can raise and lowerdepending on the terrain that is traversed by the stump cutter.

The second linkage 72 includes a first end that pivotally connects tothe control mount 60 (i.e., first linkage) and a second end thatpivotally connects to the weldment 76 (also known as the fourthlinkage). In the depicted embodiment the weldment 76 houses the controlpanel 52. In the depicted embodiment the weldment is generally verticalin the stowed position and past horizontal in the working position. Inthe depicted embodiment the change in orientation of the control panel52 is greater than 90 degrees from the stowed position to the workingposition. The third linkage 74 includes a first end that pivotallyconnects to the control mount 60 and a second end that pivotallyconnects to the weldment 76. In the depicted embodiment, a spring 78 isconnected between the control mount 60 and the third linkage 74. Spring78 acts to keep the control panel 52 in either the working position orthe stowed position. The spring 78 and lengths of the linkage arearranged such that the spring is more stretched as it moves out of thestowed position or out of the work position. The spring 78 also preventsthe control panel 52 from rattling or flipping open or closed due tovibration as the stump cutter traverses uneven ground surface.Therefore, the linkage is configured so that the control panel 52 willstay in the working position or the stowed position without the need forsecondary securing mechanisms (e.g., latches, pins, tethers, etc.)

In the depicted embodiment, the weldment 76 which houses the controlpanel 52 is protected by a shroud 80, a face plate (or decal) 82, and abottom plate 84. The shroud 80 and face plate 82 protect the controlpanel 52 from contact with objects moving towards the first end 32 ofthe machine when the control panel is in the working position, while thesecond linkage 72 and the bottom plate 84 protect the control panel 52from contact with objects. It should be appreciated that many otherconfigurations are also possible.

The above specification, examples and data provide a completedescription of the manufacture and use of the composition of theinvention. Since many embodiments of the invention can be made withoutdeparting from the spirit and scope of the invention, the inventionresides in the claims hereinafter appended.

We claim:
 1. A stump reducing machine comprising: a chassis including afirst end and a second end; an engine mounted to the chassis; a mountingmember pivotally connected to the second end of the chassis, wherein themounting member is configured to pivot about a substantially verticalaxis; a material reduction linkage assembly mounted to the mountingmember configured to enable a raising and lowering motion of a rotatablecutter wheel, the material reduction linkage assembly including: a firstlinkage pivotally mounted to the mounting member, the first linkagebeing configured to pivot about a substantially horizontal axis; asecond linkage pivotally mounted to the mounting member, the secondlinkage being configured to pivot about a substantially horizontal axis;a third linkage pivotally mounted to the first linkage and the secondlinkage, the third linkage being configured to support the rotatablecutter wheel; and wherein the material reduction linkage, via thepivotal connection between the second end of the chassis and themounting member, is configured to laterally sweep through a sweep rangerelative to the chassis thereby resulting in a sweeping motion of thematerial reduction tool for laterally engaging a stump.
 2. The stumpreducing device of claim 1, further comprising a hydraulic motor mountedto the third linkage.
 3. The stump reducing device of claim 1, furthercomprising a guard pivotally mounted to the third linkage, wherein thevariation in a tilt angle of the guard during operation is less thanabout 35 degrees.
 4. The stump reducing device of claim 1, furthercomprising a guard pivotally mounted to the third linkage and ahydraulic cylinder connected to the guard.
 5. The stump reducing deviceof claim 1, further comprising a hydraulic cylinder pivotally connectedbetween the mount member and the third linkage.
 6. The stump reducingdevice of claim 1, wherein at least one of the first and second linkagesis a hydraulic cylinder.
 7. The stump reducing device of claim 1,further comprising a first control console movably mounted such that theconsole can be positioned adjacent the second end of the chassis.
 8. Thestump reducing device of claim 1, wherein the material reduction linkageassembly is configured such that the ratio between the horizontal andvertical displacement of the material reduction tool is between about0.4 and 0.6.
 9. The stump reducing device of claim 1, wherein thematerial reduction linkage assembly is configured such that the ratiobetween X1:Y1 is between 0.0 to 0.3, wherein Y1 is the verticaldisplacement of the material reduction tool between its lowest positionto its position furthest from the mount member, and X1 is the horizontaldisplacement of the material reduction tool that corresponds with Y1.10. The stump reducing device of claim 1, wherein the material reductionlinkage assembly is configured such that the ratio between X2:Y2 isbetween about 0.5-0.7, wherein Y2 is the vertical displacement of thematerial reduction tool between its highest position to its positionfurthest from the mount member, and X2 is the horizontal displacement ofthe material reduction tool that corresponds with Y2.
 11. The stumpreducing device of claim 1, wherein the material reduction linkageassembly is configured such that the ratio between X1:Y1 is less thanthe ratio between X2:Y2, wherein Y1 is the vertical displacement of thematerial reduction tool between its lowest position to its positionfurthest from the mount member, X1 is the horizontal displacement of thematerial reduction tool that corresponds with Y1, Y2 is the verticaldisplacement of the material reduction tool between its highest positionto its position furthest from the mount member, and X2 is the horizontaldisplacement of the material reduction tool that corresponds with Y2.12. The stump reducing device of claim 1, wherein the material reductionlinkage assembly is configured such that the path of travel of thematerial reduction tool is more curved above ground than below ground.13. The stump reducing device of claim 1, wherein the sweep range isbetween 60 to 90 degrees relative to the chassis.
 14. The stump reducingdevice of claim 1, wherein the sweep range of the material reductionlinkage is independent of a vertical position of the material reductiontool.
 15. The stump reducing device of claim 1, further comprising ahydraulic cylinder pivotally connected between the mount member and thechassis, the hydraulic cylinder being configured to control a sweepingmotion of the material reduction linkage.
 16. The stump reducing deviceof claim 1, wherein a lateral sweep angle and a vertical position of thematerial reduction tool are configured to be controlled independently.17. A stump reducing machine comprising: a chassis including a first endand a second end; an engine mounted to the chassis; a mounting memberpivotally connected to the second end of the chassis, wherein themounting member is configured to pivot about a substantially verticalaxis; a material reduction linkage assembly mounted to the mountingmember configured to enable a raising and lowering motion of a rotatablecutter wheel, the material reduction linkage assembly including: a firstlinkage pivotally mounted to the mounting member, the first linkagebeing configured to pivot about a substantially horizontal axis; asecond linkage pivotally mounted to the mounting member, the secondlinkage being configured to pivot about a substantially horizontal axis;a third linkage pivotally mounted to the first linkage and the secondlinkage, the third linkage being configured to support the rotatablecutter wheel; wherein the material reduction linkage, via the mountingof the material reduction linkage to the mounting member, is configuredto laterally sweep through a sweep range relative to the chassis,thereby resulting in a sweeping motion of a material reduction tool forlaterally engaging a stump; and wherein the sweep range of the materialreduction linkage is independent of a vertical position of the materialreduction tool
 18. A stump reducing machine comprising: a chassisincluding a first end and a second end; an engine mounted to thechassis; a mounting member pivotally connected to the second end of thechassis, wherein the mounting member is configured to pivot about asubstantially vertical axis; a material reduction linkage assemblymounted to the mounting member configured to enable a raising andlowering motion of a rotatable cutter wheel, the material reductionlinkage assembly including: a first linkage pivotally mounted to themounting member, the first linkage being configured to pivot about asubstantially horizontal axis; a second linkage pivotally mounted to themounting member, the second linkage being configured to pivot about asubstantially horizontal axis; a third linkage pivotally mounted to thefirst linkage and the second linkage, the third linkage being configuredto support the rotatable cutter wheel; wherein the material reductionlinkage, through the mounting thereof to the mounting member, isconfigured to laterally sweep through a sweep range relative to thechassis, thereby resulting in a sweeping motion of a material reductiontool for laterally engaging a stump; and wherein the lateral sweepingmotion of the material reduction tool and a raising and lowering motionof the material reduction tool are configured to be controlledindependently of one another.
 19. The stump reducing machine of claim 1,wherein the raising and lowering of the material reduction tool canoccur under one of the following conditions: 1) without any lateralsweeping motion; and 2) with a lateral sweeping motion in either aleft-to-right or a right-to-left direction.